Rectangular pulse modulator

ABSTRACT

Discharge of a RLC network is controlled with a siliconcontrolled rectifier to provide a rectangular pulse for pulsing GaAs lasers.

United States Patent Inventors Jimmy R. Duke; [561 References Cited Walter E. Miller, Jr., Huntsville Ala. UNITED STATES PATENTS Q53;

1968 3,181,071 4/1965 Smith et a1 328/65 3,371,232 2/1968 Hannan'et a1 307/212 Patented May 4, 1971 Assignee the United States of America as represented OTHER REFERENCES by the Secretary of the Army Missles and Rockets June 10, 1963 Vol. 12, No. 23 page 33 GE Developed Laser System Offers High Pulse Rate (copy enclosed) Electronics, May 31, 1963, Diode Laser Transrnits Audio (copy enclosed) RECTANGULAR PULSE MODULATOR 2 claims, 6 Drawing as. Primary Exammer-John S. Heyman Attorneys-Harry M. Saragovnz, Edward J. Kelly, Herbert US. 284, Ber and Aubrey J Dunn 307/268, 307/312, 333/20, 307/ 108, 331/945 Int. CL H03k 3/35 field of Search 307/268, ABSTRACT: Discharge of a RLC network is controlled with a 284, 312, I06, 8; 328/65; 331/945, (Inquired); silicon-controlled rectifier to provide a rectangular pulse for 333/20 pulsing GaAs lasers.

VOE'IGAGE 66 SOURCE R2\ oz 1 PATENTED m 419? DC VOLTAGE SOURCE INPUT FIG. 3

FIG.5

INVENTORS.

a a mm m WW M RE yr m my a w 6 .m. C! H -.to I50 amperes with durations (pulse width) of 200 nanoseconds or less. One method of achieving these requirements is the discharge of .a small, high voltage capacitor through the laser usinga silicon-controlled rectifier as the switch. This results in a current having a highly peaked triangular waveform when the capacitor is discharged through a very low impedance, approximately I ohm. When discharged through the higher irnpedances encountered in laser arrays, the waveform is similar in rise time, but exhibits a much slower delay characteristic.

' Current driven through a laser below the threshold level not only provides no useable optical output, but serves to heat the laser and raise the threshold level. Thus, it is desirable to drive the laser with a very fast rise time current with essentially a flat top and a sharp cutoff. Rectangular pulses of durations and current levels required are not obtainable with simple solidstate modulators. Normal delay lines provide a rectangular I pulse' only when discharged into a constant impedance. For

this reason, delay lines are not desired for use with lasers since lasers present a varying impedance.

SUMMARY OF THE INVENTION A silicon-controlled rectifier is used to control the discharge of a parallel combination of capacitors, resistors and inductors to provide a desired pulse of current.

BRIEF DESCRIPTION OF THE DRAWING FIG. I is a schematic diagram of the present invention. FIGS. 2-6 are current waveforms.

DESCRIPTION OF THE PREFERRED EMBODIMENT Referring now to FIG. I, the silicon-controlled rectifier,

SCR, controls the discharge of RLC network 4. The components of RIJC network 4 are chosen to approximate a square wave output when they are discharged. During thecharge cycle, current flows from voltage supply 6, through RLC network 4 and charging diode 8. When the SCR is keyed ON by the trigger input means 12, RLC network 4 discharges determining the discharge pulses from RLC network 4.

FIG. 2 shows the waveform, obtained. when a 0.003- microfarad capacitor charged to 800 volts is discharged through a 3-ohm dummy load. FIG. 3 shows the current waveform when a IO-ohm resistor is added in series with the capacitor. The rise time of the pulse is the same as before, but

the amplitude is less and the delay time is longer. FIG. 4 shows the current waveform when the lO-ohm resistor is replaced by a 0.5-microhenry inductor. Increased rise time as well as decreased amplitude and increased delay time results. FIG. 5 shows two superimposed waveforms of the type shown in FIGS. 3 and 4, but with such values that when they are triggered by the same SCR, the waveform of FIG. 6 results.

As an example, to obtain an output waveform as shown in FIG. 6, typical values would be:

C1=0.0002 microfarads C2=0.0015 microfarads C3=0.0043 microfarads L=0.5 microhenries Rl= l 00,000 ohms The particular laser diode used presented a 3-ohm load to the RLC network.

We claim: l. A rectangular pulse modulator comprising: a RLC network having a first, second, and third capacitor, a resistor, and an inductor; a silicon-controlled rectifier having an anode, cathode and trigger input, said cathode being connected to ground; a voltage source connected to a first side of said RLC network and to the anode of said silicon-controlled rectifier; a diode having its anode connected to a second side of said RLC network and its cathode connected to ground; a laser diode having its anode connected to ground and its cathode connected to said second side of said RLC network; and said first capacitor being connected between said first side and said second side of said RLC network, said resistor and said second capacitor being connected in'series between said first and second side of said RLC network, said inductor and said third capacitor being connected in series between said first and second side of said RLC network, and said values of said first, second, and third capacitors, said resistor, and said inductor being such that the pulse produced when said RLC network is discharged is essentially a square pulse.

2. A rectangular pulse modulator as set forth in claim 1, further including a trigger input means connected to said trigger input of said silicon-controlled rectifier, said means providing a periodic pulse necessary to key said silicon-controlled rectifier into conduction. 

1. A rectangular pulse modulator comprising: a RLC network having a first, second, and third capacitor, a resistor, and an inductor; a silicon-controlled rectifier having an anode, cathode and trigger input, said cathode being connected to ground; a voltage source connected to a first side of said RLC network and to the anode of said silicon-controlled rectifier; a diode having its anode connected to a second side of said RLC network and its cathode connected to ground; a laser diode having its anode connected to ground and its cathode connected to said second side of said RLC network; and said first capacitor being connected between said first side and said second side of said RLC network, said resistor and said second capacitor being connected in series between said first and second side of said RLC network, said inductor and said third capacitor being connected in series between said first and second side of said RLC network, and said values of said first, second, and third capacitors, said resistor, and said inductor being such that the pulse produced when said RLC network is discharged is essentially a square pulse.
 2. A rectangular pulse modulator as set forth in claim 1, further including a trigger input means connected to said trigger input of said silicon-controlled rectifier, said means providing a periodic pulse necessary to key said silicon-controlled rectifier into conduction. 